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Antibacterial Activity and Mode of Action of a SulfonamideBased Class of Oxaborole Leucyl-tRNA Synthetase Inhibitors Yuanyuan Si, Sneha Basak, Yong Li, Jonathan Merino, James N. Iuliano, Stephen G Walker, and Peter J Tonge ACS Infect. Dis., Just Accepted Manuscript • DOI: 10.1021/acsinfecdis.9b00071 • Publication Date (Web): 22 Apr 2019 Downloaded from http://pubs.acs.org on April 22, 2019
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Antibacterial Activity and Mode of Action of a Sulfonamide-Based Class of Oxaborole Leucyl-tRNA Synthetase Inhibitors Yuanyuan Si‡, Sneha Basak‡, Yong Li‡, Jonathan Merino‡, James N. Iuliano‡, Stephen G. Walker§, Peter J. Tonge#¶‡*
#Center
for Advanced Study of Drug Action, Department of ‡Chemistry, ¶Radiology and §Oral
Biology and Pathology, John S. Toll Drive, Stony Brook University, Stony Brook, New York 11794, USA
*Author to whom correspondence should be addressed. Peter J. Tonge: Department of Chemistry, Stony Brook University, Stony Brook, NY 11794-3400 Tel: (631) 632 7907. Email:
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Benzoxaboroles are a class of boron-containing compounds with a broad range of biological activities. A subset of benzoxaboroles have antimicrobial activity due primarily to their ability to inhibit leucyl-tRNA synthetase (LeuRS) via the oxaborole tRNA trapping mechanism, which involves formation of a stable tRNALeu–benzoxaborole adduct in which the boron atom interacts with the 2- and 3-oxygen atoms of the 3-terminal tRNA adenosine. We sought to identify other antibacterial targets for this promising class of compounds by means of mode of action studies, and we selected a nitrophenyl sulfonamide-based oxaborole (PT638) as a probe molecule because it had potent antibacterial activity (MIC of 0.4 µg/mL against methicillinresistant Staphylococcus aureus) but did not inhibit LeuRS (IC50 > 100 µM). Analogues of PT638 were synthesized to explore the importance of the sulfonamide linker and the impact of altering the functionalization of the phenyl ring. These structure–activity relationship studies revealed that the nitro substituent was essential for activity. To identify the target for PT638, we raised resistant strains of S. aureus and whole genome sequencing revealed mutations in leuRS, suggesting that the target for this compound was indeed LeuRS, despite the lack of enzyme inhibition. Subsequent analysis of PT638 metabolism demonstrated that bacterial nitroreductases readily converted this compound into the amino analogue, which inhibited LeuRS with an IC50 of 3.0 ± 1.2 µM demonstrating that PT638 is thus a prodrug.
Keywords: LeuRS, oxaborole, nitroreductase, nitro prodrug, S. aureus, resistance
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Multidrug-resistant bacteria are a major threat to human health because they cause infections that are hard to treat and often life-threatening.1,2 Drug resistance arises by a variety of mechanisms, including conversion of a drug into inactive metabolites, modification of drug binding sites, changes in cell permeability or drug efflux, and the formation of bacterial populations, such as biofilms, that are less susceptible to antibiotics.3,4 One particularly problematic pathogen is methicillin-resistant Staphylococcus aureus (MRSA), which is resistant to numerous antibiotics, including most β-lactams,5 macrolides, fluoroquinolones, and aminoglycosides.6 The threat posed by multidrug-resistant pathogens such as MRSA underscores the need to develop antibiotics with novel mechanisms of action. The benzoxaboroles are a versatile class of small molecules with potential utility as antibiotics because their selectivity and specificity can be tuned by minor structural modifications. Targets for these compounds include β-lactamases,7 PDE4 nucleotide phosphodiesterase,8 ROCK kinase,9 carbonic anhydrase,10 and leucyl-tRNA synthetase (LeuRS).11 The oxaborole scaffold can reversibly form covalent tetrahedral complexes with nucleophiles such as hydroxyl groups owing to the presence of the heterocyclic boron atom, which acts as a Lewis acid because it has an empty p orbital.12,13 Formation of such complexes is involved in LeuRS inhibition, which occurs via the oxaborole tRNA trapping (OBORT) mechanism (Figure 1), whereby the boron atom forms a tetrahedral complex with both hydroxyl groups of the ribose diol of the terminal 3 tRNA adenosine. Enzyme inhibition via the formation of an enzyme–substrate adduct is also observed in other drug classes, such as the bacterial enoyl-ACP reductases, which are inhibited by isoniazid and diazaborines.14,15 Anacor Pharmaceuticals has developed a number of oxaborole-based inhibitors of LeuRS from bacteria, fungi, protozoa, and other pathogens (Figure 1). AN2690,11 which has broad-spectrum antifungal activity, is one of the most effective US Food and Drug
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Administration–approved treatments for onychomycosis,16 while AN6426 is an inhibitor of the Mycobacterium tuberculosis LeuRS (minimum inhibitory concentration, MIC 0.13 µM, M. tuberculosis LeuRS IC50 0.09 µM),17 which also has antimalarial activity,18 and inhibits the growth of Cryptosporidium and Toxoplasma.19 20 Finally, AN3365, an aminomethylbenzoxaborole, binds to the editing site of Escherichia coli LeuRS with an IC50 value of 0.31 µM and has broad-spectrum activity against Gram-negative pathogens (MIC 0.5–4 µg/mL).21,22
OH NH2 N
tRNA
O
O O
N
N
HO
O
O
AN2690 O
B
AN3365
OH
O2N
B
H N
O
R
OBORT mechanism
OH B
F
N
O
O
B
Cl
NH2
AN6426
S O O
NH2
OH B O
PT638
Figure 1. OBORT mechanism and oxaborole-based enzyme inhibitors.
Given the good drug-like properties of the oxaborole scaffold and given that both laboratory and clinical isolates show resistance to LeuRS-based inhibitors (arising mainly from mutations in the LeuRS editing domain),23,24 we sought to identify new antibacterial targets for this promising class of compounds. Building on the extensive medicinal chemistry efforts conducted by Anacor, we identified the nitrophenylsulfonyl-substituted 6-aminobenzoxaborole PT638 as a probe molecule (Figure 1). This compound was previously reported to have a MIC value of < 0.2 µg/mL against S. aureus but to not inhibit LeuRS (IC50 > 200 µM).25 We conducted structure–activity relationship (SAR) studies to explore the importance of the nitro group,
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sulfonamide linker region, and oxaborole ring for biological activity. These studies revealed that the nitro group was essential for activity. However, whole genome sequencing of resistant bacterial strains suggested that this compound did in fact target LeuRS, despite the lack of enzyme inhibition. Investigation of the mode of action of PT638 revealed that this compound is reduced to the active species by nitroreductases in MRSA cells.
Results and Discussion SAR for inhibition of bacterial growth We began by determining the antibacterial activity of PT638 toward MRSA (ATCC BAA1762) and found that the MIC was 0.4 µg/mL (Table 1). Similarly, we assessed the cytotoxicity of PT638 to Vero cells using an MTT assay and determined the IC50 to be 100 g/mL (Table 1). We subsequently performed SAR studies by synthesizing three series of PT638 analogues; specifically, we introduced modifications to the substituent on the phenyl ring (SAR1), to the sulfonamide linker (SAR2), and to the oxaborole ring (SAR3) and determined the antibacterial activity of the analogues, as well as their ability to inhibit S. aureus LeuRS (saLeuRS) (Figure 2, Table 1).
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Table 1. Biochemical activities of oxaboroles with MIC values 100
0.4
100
>100
1.56
N.D.
>100
6.25
N.D.
3.0 ± 1.2
3.125
100
28 ± 1
6.25
N.D.
OH
H N
PT660
(IC50 µg/mL)
OH
H N
PT662
(µg/mL)
OH
H N
O O
PT659
Vero cells
OH
H N
O O
PT650
MRSA
OH
H N
O O
PT638
Cytotoxicityc
IC50 (µM)a
Structure
PT649
MICb
O
OH B O
aIC
50 values were measured by means of a radiolabeled LeuRS aminoacylation assay.
bMIC against
MRSA ATCC BAA-1762 was determined using a broth microdilution method. cCytotoxicity was determined with Vero cells using an MTT cell viability assay. All measurements were performed in triplicate and standard errors are reported. N.D., not determined.
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Figure 2. Structure–activity relationships (SARs) for inhibition of bacterial growth. Three series of analogues were synthesized to explore SAR associated with the substituent on the phenyl ring (SAR1), the sulfonamide linker (SAR2), and the oxaborole ring (SAR3). MIC values (g/mL) against MRSA (ATCC BAA-1762) were determined by broth microdilution; values of < 10 µg/mL are indicated in red.
With the SAR1 analogues, we explored the importance of the 4-nitro group for antibacterial activity (Figure 2). We expected that a strongly electron-withdrawing group like the nitro group would be required for activity, and, in fact, removing the nitro group (PT649) or replacing it with an electron-donating methyl group (PT637) or methoxy group (PT661) did lead to 10-, 100-, and >250-fold increases in MIC, respectively. However, neither replacement of the 4-nitro group with
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another electron-withdrawing group such as a cyano moiety (PT657, MIC >100 g/mL) nor relocation of the nitro group to the 2-position (PT659, MIC 6.25 g/mL) restored the activity to that of the parent compound. When we replaced the 4-nitro group with various 4-halogen atoms, we found that increasing the size of the halogen atom decreased the antibacterial activity: specifically, the 4-fluoro (PT636), 4-chloro (PT651), and 4-bromo (PT654) analogues had MICs of 12.5, 100, and >100 g/mL, respectively. However, even the most active analogue (4-fluoro) had a MIC value that was 30-foldless than that of PT638. In addition, activity did not depend on the position of the fluorine atom: the 2-fluoro (PT660) and 3-fluoro (PT653) analogues had MICs similar to that of PT636. Other substituents were also explored, but none of the resulting analogues, including 3-fluoro-4-nitro analogue PT650 and 4-amino analogue PT662, were as active as PT638. Collectively, these data attest to the critical importance of the 4-nitro group for antibacterial activity. We subsequently explored the contributions of the sulfonamide linker and the oxaborole ring with the analogues in the SAR2 and SAR3 series, respectively (Figure 2). We found that regardless of whether the phenyl ring carried a 4-nitro or 4-fluoro substituent, replacement of the sulfonamide linker with an amine or amide linker substantially reduced antibacterial activity. All three linker analogues are able to adopt similar, although not identical conformations, while replacement of the sulfonyl moiety with a carbonyl (amide) or methylene (amine) group reduces the number of hydrogen bond acceptors at this position to 1 and 0, respectively (Figure S1). Thus, either the change in geometry and/or alteration in hydrogen bonding propensity may perturb binding to the target. In addition, the oxaborole ring was also critical for activity, as expected for molecules that might exert their activity via the OBORT mechanism; replacement of the oxaborole ring with a lactone (PT664) or a boronic acid group (PT663) dramatically reduced the activity.
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Time-kill experiments and post-antibiotic effect of PT638 To further assess the antibacterial activity of PT638, we conducted time-kill experiments and determined the duration of the post-antibiotic effect following removal of the test compound from the medium. Treatment of MRSA cells with PT638 at concentrations 1, 4, and 16 times the MIC led to 1.8 log10, 2.2 log10, and 2.7 log10 cfu/mL reductions in cell numbers over 8 h, respectively (Figure 3A). That is, PT638 showed bacteriostatic activity over the course of 8 h, as indicated by the fact that the cfu reduction was